PMMA Nanocomposites Synthesized by Emulsion Polymerization

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Chapter 3 PMMA Nanocomposites Synthesized by Emulsion Polymerization 1,3

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Sumanda Bandyopadhyay , Alex J . H s i e h , and Emmanuel P. Giannells

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Department of Materials Science and Engineering, Bard Hall, Cornell University, Ithaca, NY 14853 A M S R L - W M - M A , Army Research Laboratory, Aberdeen Proving Ground, Aberdine, MD 21005 Current address: G E India Technology Centre, Expost Prom. Industrial Park, Ph-2, Whitefield Road, Bangalore 560066, India 2

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Well-dispersed (exfoliated) PMMA nanocomposites were synthesized via emulsion polymerization. The nanocomposites retain their transparency in the visible with the montmorillonite nanocomposite showing considerable absorption of UV light. Thermal stability of the nanocomposites is enhanced as evidenced by T G A and a simple burning experiment. The storage modulus and Tg is increased significantly in the nanocomposites. The higher increase of the storage modulus in the rubbery regime of the montmorillonite nanocomposite reflects the higher amount of bound polymer compared to the fluorohectorite nanocomposite.

Nanocomposites based on layered inorganics offer an alternative to conventionally filled polymers and composites. Due to their nanometer phase dimensions the nanocomposites exhibit new and improved properties. These include increased stiffness and strength without sacrificing impact resistance, decreased permeability and swelling in solvents, and increased flame resistance. For example, nylon nanocomposites show a significant increase in modulus and strength as well as heat distortion temperature. (1,2). Tensile strength and modulus have also been reported to increase considerably in epoxy and polyurethane nanocomposites (2-8). Additionally improved barrier properties (9, © 2002 American Chemical Society

In Polymer Nanocomposites; Krishnamoorti, R., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2001.

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10) and swelling in solvents (11) have been reported for several nanocomposite systems. Finally the nanocomposites exhibit increased thermal stability and flame resistance (12-15). Currently, two synthetic approaches have been adopted. One is based on in-situ polymerization of monomers inside the galleries of the inorganic host. (16-20). The other approach is based on melt intercalation of high molecular weight polymers and it involves annealing a mixture of the polymer and the inorganic host, statically or under shear, above the Tg of the polymer (21-24). The solventless melt intercalation is an environmentally friendly technique and is adoptable to existing processing like roll milling, extrusion and molding. In the present chapter, we report the synthesis of PMMA nanocomposites by emulsion polymerization. Polymerization of M M A in the presence of smectite silicates has been previously reported (25-28). The focus of all these studies, however, was on how the silicates affect the polymerization reaction rather than the final hybrid product. Additionally, the development of an emulsion route to nanocomposites represents a new avenue. Experimental 5 ml of M M A (Sigma Chemicals) was added to a round bottom flask containing 95 ml of water (the ratio of monomer to water is approximately 1:19) followed by 0.25 g of silicate (Na montmorillonite, hereafter abbreviated as MMT, or fluorohectorite, FH). The resulting suspension was heated at 80°C with stirring and allowed to equilibrate for 2 hrs. An emulsifier (sodium lauryl sulfate, 0.25 g) is added to allow the reaction to proceed as emulsion polymerization with constant mechanical stirring. 0.0125 g of potassium persulfate is added to initiate the polymerization and the suspension is refluxed at 80°C for 4 hrs.. The emulsion is completely precipitated in excess ethyl alcohol. The precipitate is then filtered and re-precipitated from tetrahydrofuran, washed thoroughly with de-ionized water,filteredand dried under vacuum at 80°C. In one particular case the MMT was modified with 2,2' Azobis(2-methylpropionamide) dihydrochloride and hereafter referred to as AMMT. A schematic (Scheme 1) shows the synthetic route and also the silicate modification. +

Table 1: Summary of PMMA and PMMA Nanocomposites Properties

Polydispersity index, D Molecular Weight (g/mol) X 10 Glass Transition Temp. T g , (°C) Storage Modulus @ RT (GPa) MMT: montmorillonite FH: fluorohectorite

PMMA 3.49 195.2

PMMA-MMT 2.57 221.7

PMMA-FH 2.59 223.0

115 2.9

121 9.9

125 9.3

f

The molecular weight of the extracted nanocomposites samples was done on Waters GPC instrument with refractive index attachment using polystyrene standard. X-Ray diffraction was performed using a Scintag PAD X

In Polymer Nanocomposites; Krishnamoorti, R., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2001.

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Schematics for the silicate modification and emulsion polymerization of PMMA nanocomposites

Chfe H N 2

C—C-N=N—C NH

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Chfe N H

Chfe

C

Nhb

.2HC1

Chfe

2,2' Azobis(2-methylpropionamide) dihydrochloride

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18 Diffractometer using Cu-Ka radiation. The accelerating voltage used was 45kV and the current was 40mA. The T E M samples were examined using JEOL 1200EX transmission electron microscope with an accelerating voltage of 120kV. Samples of 0.2 /Jm to 0.3 jum thickness were cut using a glass knife Reichert Ultramicrotome and mounted on 400 mesh Gilder gold grid. Thermal degradation was followed by a Perkin Elmer System 7, Thermogravimetric Analyzer. Scans were performed from room temperature to 800 °C at 10 °C/min. For dynamic mechanical analysis a Seiko Instrument, SDM 5200, DMS 200 series was used. The samples were scanned from room temperature to 150°C at 2°C/min at 5Hz and a strain of 0.1%. Absorbance was measured between 200nm and 900nm at a spectral bandwidth of 1 nm and a scan speed of 30nm/sec on a Perkin Elmer spectrophotometer. Results and Discussion TEM micrographs of the nanocomposites prepared via emulsion show a well dispersed (exfoliated) sample (Fig. 1). The dispersion is somewhat better in the MMT nanocomposite and is most likely due to the much smaller lateral dimensions of MMT compared to FH. The silicate exfoliation is supported by the featureless XRD patterns (Figures not included) of the nanocomposites.

Figure 1: Transmission electron microscope showing the disordered silicate (montmorillonite) in the PMMA matrix. Table 1 summarizes the molecular weight and the polydispersity of the polymers for all samples prepared by emulsion polymerization. The nanocomposites show

In Polymer Nanocomposites; Krishnamoorti, R., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2001.

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19 slightly higher molecular weights but much better polydispersity than pure PMMA prepared similarly but in the absence of the silicate. Though the mechanism is still unknown, clearly the presence of silicate effects the polymerization reaction. Clarity of the samples is very important as PMMA is often used in many applications for its transparency. Films were deposited on clean glass substrates by spin casting a suspension of the nanocomposites in tetrahydrofuran, THF. For comparison a PMMA film was prepared by spin casting a solution of PMMA also in THF. The nanocomposites have somewhat higher absorbance compared to the pure polymer, but the absorbance is well below the limit for transparency. Especially in the case of MMT nanocomposite the sample shows increased absorption in the UV. Thus the nanocomposites combine UV absorption while retaining transparency in the visible. An important characteristic of polymers is their stability at elevated temperatures. Figure 2 and 3 shows the TGA traces of the pure polymer and the nanocomposites in either nitrogen or oxygen. Thermal degradation of PMMA in nitrogen proceeds in three distinctive steps. Thefirst(low temperature) is due to decomposition of relatively weak head-to-head linkages, the second to chain-end decomposition and the third to random scission within the polymer chain (29). In the present case degradation of PMMA in nitrogen (Fig. 2) follows a two-step process (thefirststep is absent). The onset of the two steps is at 322 and 380 °C, respectively. The FH nanocomposite appears to decompose also in two steps. The derivative shows that the extent of the two steps is reversed from the corresponding PMMA sample. At the same time, the second peak moves to a slightly higher temperature. In contrast, decomposition of the M M T nanocomposite follows a single step suggesting that only decomposition by random scission takes place. In contrast to nitrogen, oxygen suppresses the degradation of weak linkages at low temperatures but it enhances the degradation via random scission at higher temperatures for the pure PMMA. Similarly to the pure polymer the nanocomposites show one major decomposition step (Fig. 3). The onset decomposition of FH nanocomposite, however, commences a little earlier but it extends to somewhat higher temperatures than the pure PMMA. In contrast, MMT nanocomposites show a large suppression of decomposition compared to the pure polymer with the decomposition temperature increasing by about 50 °C. Blumstein (25) mentioned that increased thermal stability is not only due to the particular structure of the inserted polymer but stearic factors also have an important role to play in the thermal motion of the chain segments in between the clay lamellae. It is also important to point that the extent of polar interaction due to exfoliation of the clay lamellae in the present PMMA nanocomposites could be responsible for a higher thermal stability of the composite system. The

In Polymer Nanocomposites; Krishnamoorti, R., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2001.

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Figure 2: Thermogravimetric traces of the different PMMA nanocomposites in nitrogen.

In Polymer Nanocomposites; Krishnamoorti, R., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2001.

- Pure P M M A

100 -L

- PMMA-MMT PMMA-FH

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40 20

in Air 200

500

300 400 Temperature, C

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Pure P M M A PMMA-MMT

in Air -2.0 200

PMMA-FH

300

!

400

500

Temperature, °C

Figure 3: Thermogravimetric traces of the different PMMA nanocomposites air.

In Polymer Nanocomposites; Krishnamoorti, R., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2001.

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22 difference of polar interaction existing in M M T and F H could lead to the formation of a different polymer microstructure and hence a difference in the thermal behavior. There are clearly differences between the two nanocomposites and the pure polymer. In addition, the thermal stability depends i f air or nitrogen is used. We are currently attempting to understand and delineate the factors contributing to this behavior. Nevertheless, the thermal stability of the polymer appears to increase in the nanocomposites. The above conclusion is corroborated by a simple burning test using a propane torch. P M M A burns out completely with significant dripping. In contrast, the nanocomposites experience no dripping during burning. Furthermore, the M M T nanocomposite self-extinguishes shortly after the flame is removed. The F H nanocomposite continues to burn but it forms a significant amount of char, which is characteristic of higher thermal stability. Solomon et al. has observed that clay minerals act as inhibitor for free radical polymerization specifically for P M M A (30). The clay minerals inhibit the free radical reactions by preferential absorption of the propagating or initiating radicals by the Lewis acids and then the reaction either gets terminated by dimerization or disproportionation or by formation of a carbonium ion by electron transfer from the radical to the Lewis acid site. The clay minerals usually made of aluminosilicates and minerals containing higher amount of aluminosilicates are more effective inhibitors. In the present case, M M T is an aluminosilicate while F H contains M g in the octahedral layer (31). Thus, M M T contains Lewis acid sites but not F H . This might explain the different behavior between the two silicates, M M T and F H , in the nanocomposites. Recently Gilman et.al. (32) observed a difference in the flammability behavior of M M T and F H based nanocomposites. They observe a silicate layer reassemble into a multiplayer char after the polymer burns away. The smaller size of M M T lamellae could assist in the reassemble process compared to the large F H lamellae, which disrupts the char formation. Finally dynamic mechanical analysis was used to measure the viscoelastic properties of the nanocomposites as a function of temperature. In this measurement the in-phase and out-of-phase components of the stress are measured while a sinusoidal strain is applied to the sample. From the in-phase and out-of-phase components the storage (E') and loss modulus (E"), respectively, can be calculated. The ratio E'VE' = tanS is a measure of the energy lost to energy stored per cycle of deformation and has a maximum at thermal transitions. The D M A measurements for storage modulus, E \ with temperature for M M T and F H nanocomposites and pure P M M A are shown in Figure 4. A n increase of 6°C in Tg was evident in M M T nanocomposite; the exfoliated silicate-PMMA hybrid resulted from the emulsion polymerization is attributed to this increase in Tg. In addition, the D M A data revealed an-order-ofmagnitude increase in the rubbery plateau modulus for the M M T nanocomposite

In Polymer Nanocomposites; Krishnamoorti, R., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2001.

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23 compared to the pure P M M A . This increase was significant and consistent over the temperature used in this study. Enhancement in the thermo-mechanical properties of P M M A Nanocomposites prepared by emulsion polymerization was also evident in the F H nanocomposite. The latter exhibited an increase of 10°C in Tg and higher E ' values above Tg, compared to pure P M M A . However, the increase in the rubbery plateau modulus obtained in D M A was more significant in the M M T than that in F H . This trend might reflect the differences in the amount of strongly interacting polymer (bound polymer) for the two nanocomposites. After extraction in chloroform at room temperature M M T retains 40 % polymer while only 7 % is left in F H . The much higher amount of bound polymer in M M T might act as potential crosslinks increasing the rubbery modulus to a greater extent.

10000

1000

\

v

\

o

v

\ \ .*\

100

Bending Modulus, 1Hz !

PMMA (Pure)

:

PMMA-MMT



PMMA-FH

0

50

100

150

Temperature, (°C)

Figure 4: Dynamic mechanical analysis plots for the different PMMA nanocomposites Table 2 summarizes the results from the characterization of the P M M A end-tethered M M T samples. These samples were prepared by suspension polymerization of M M A in the presence of A M M T . The silent X R D refers to a well dispersed silicate morphology. The Tg from the D M A analysis, however, shows a very slight increase in the temperature and a much higher increase in the rubbery plateau modulus. The increase in the rubbery plateau modulus is evident from the amount of the bound polymer in the A M M T nanocomposite as compared to the M M T (un-tethered) samples.

In Polymer Nanocomposites; Krishnamoorti, R., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2001.

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Table 2: X-ray diffraction and Thermal and Bound Polymer of the nanocomposites XRD Bound Samples XRD DMA, Polymer Initial, Final, Tg°C nm nm — -Pure 109.3 PMMT 40% 1.106 121.8 Silent P50 82% 1.209 Silent 126.5

Conclusion The first synthesis of well-dispersed (exfoliated) P M M A nanocomposites via emulsion polymerization is described. The nanocomposites retain their transparency in the visible with the M M T nanocomposite showing considerable absorption of U V light. Thermal stability of the nanocomposites is enhanced as evidenced by T G A and a simple burning experiment. The storage modulus and Tg is increased significantly in the nanocomposites. The higher increase of the storage modulus in the rubbery regime of the M M T nanocomposite reflects the higher amount of bound polymer compared to the F H nanocomposite. Endtethering of M M T to P M M A increases the amount of bound polymer Acknowledgement This work was supported in part by NIST, A R O and Rohm and Haas. We benefited from the use of C C M R central facilities supported by NSF. References 1. Kojima, Y . ; Usuki, A . ; Kawasumi, M.; Okada, A . ; Fukushima, Y . ; Kurauchi, T.; Kamigaito, O., J. Mater. Sci., 1993, 8, 1185. 2. Kojima, Y . ; Usuki, A . ; Kawasumi, M.; Okada, A . ; Fukushima, Y . ; Kurauchi, T.; Kamigaito, O., J. Polym. Sci, Pt. A, Polym. Chem., 1993, 31, 983. 3. Lan, T.; Kaviratna, P.D.; and Pinnavaia, T.J., Chem. Mater., 1996, 8, 2628. 4. Lan, T.; and Pinnavaia, T.J., Chem. Mater., 1994, 6, 2216. 5. Wang, J.; Lan, T.; Pinnavaia, T.J., Chem Mater., 1994, 6, 468. 6. Wang Z.; and Pinnavaia, T.J., Chem. Mater., 1998, 10, 3769. 7. Zilg, C.; Thomann, R.; Mulhapt R.; and Finter, J., Adv. Mater., 1999, 11, 49 8. Newaz, G . M . , Polym. Comp., 1986, 7, 176. 9. Messersmith, P.B.; Giannelis, E.P., J. Polym. Sci, Pt. A, Polym. Chem., 1995, 33, 1047.

In Polymer Nanocomposites; Krishnamoorti, R., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2001.

25 10. Kojima, Y . ; Usuki, A . ; Kawasumi, M.; Okada, A . ; Fukushima, Y.; Kurauchi, T.; Kamigaito, O., J. Appl. Polym Sci., 1993, 49, 1259. 11. Burnside, S.D.; Giannelis, E.P., Chem. Mater., 1995, 7, 1597. 12. Lee, J.D.; Takekoshi, T.; Giannelis, E.P., Mat. Res. Soc. Symp. Proc., 1997, 457, 513. 13. Gilman, J.W.; Kashiwagi, T.; Lichetenhan, J.D.; Giannelis, E.P.; Manias, E . , 6 European Meeting on Fire Retardancy of Polymeric Materials, Lille, France, September, 24, 1997. 14. Lee, J.D.; Giannelis, E.P.,Polymer Preprints, 1997, 38, 688. 15. Gilman, J.W.; Kashiwagi, T.; Lichetenhan, J.D., S A M P E Journal, 1997, 33, 40. 16. Usuki, A . ; Kojima, Y.;.Kawasumi, M.; , Okada A . ; Fukushima, Y.; Kurauchi, T.; Kamigaito, O., J. Mater.Sci.,1993, 8, 1179. 17. Fukushima, Y.; Okada, A . ; Kojima, Y . ; Kawasumi, M.; Kurauchi, T.; Kamigaito, O., Clay Miner., 1988, 23, 27. 18. Lan, T.; Kaviratna, P.D.; Wang, M . S . ; Pinnavaia, T.J., Mater. Res. Soc. Symp. Proc.,1994, 346, 81. 19. Messersmith, P.B.; Giannelis, E.P., Chem. Mater., 1993, 5, 1064. 20. E.P. Giannelis, Adv. Mater., 1996, 8, 29. 21. Vaia, R.; Ishii, H.; Giannelis, E.P.; Chem. Mater.,1993, 5, 1064. 22. Vaia, R.; Vasudevan, S.; Kraweic, W.; Scanlon, L . G . ; Giannelis, E.P., Adv. Mater., 1995, 7, 154. 23. Usuki, A . ; Kato, M.; Okada, A . ; Kurauchi, T., J.Appl. Polym Sci.,1997, 63, 137. 24. Usuki, A . ; Kato, M.; Okada, A . J.Appl. Polym Sci.,1997, 66, 1781. 25. Blumstein, A . , J. Polym. Sci., Pt. A , 1965, 3, 2665.

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th

26. Bhattacharya, J.; Chakraborti, S.K.; Talapatra, S.; J. Polym. Sci, Pt. A, Polym. Chem.,1989, 27, 3977. 27. Biasci, L . , Aglietto, M., Ruggerio, G., Ciardelli, F., Polymer, 1994, 35, 3296. 28. M . M . Al-esaimi, J.Appl. Polym Sci., 1997, 64, 367. 29. Hirata, T., Kashiwagi, T., and Brown, J.E., Macromolecules, 1995, 18, 1410. 30. Solomon, D.H., Swift, J.D., J.Appl. Polym Sci., 1967, 11, 2567. 31. Newman, A.C.D., Chemistry of Clays and Clay Minerals, Mineralogical Society Monograph, Number 6, Wiley-Interscience, New York, 1987. 32. Giman,J.W., Jackson, C.L.,Morgan, A . B . , Harris, R.,Manias, E . , Giannelis, E.P., Wuthenow, M., Hilton, D., and Pillips, S.H., Chem. Mater., 2000, 12, 1866.

In Polymer Nanocomposites; Krishnamoorti, R., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2001.